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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B8, 2012 
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia 
GROUND-BASED CLOUD OBSERVATION FOR SATELLITE-BASED CLOUD 
DISCRIMINATION AND ITS VALIDATION 
M. Yamashita *, M. Yoshimura ° 
* Survey College of Kinki, 1-5-9 Yata, Higashi-sumiyoshi-ku, Osaka, 546-0023, Japan -yamashita@kinsoku.ac.jp 
? PASCO Corporation, Research and Development Center, 2-8-11 Higashiyama, Meguro-ku, Tokyo, 153-0043, Japan — 
mairtu1698@pasco.co.jp 
Commission VIII, WG VIII/3 
KEY WORDS: Atmosphere, Weather, Development, Application, Radiation, Observations 
ABSTRACT: 
Solar radiation is a source of energy for ground surfaces. Clouds control energy budget on both local and global scales. 
We propose the simple ground-based observation method for various sky conditions instead of the existing visual observation. 
In the paper, we mainly describe how to discriminate clouds area on whole sky images, how to overlay the cloud areas to the 
satellite-based images and the test experiment. As for the discrimination of sky conditions, we use Sky Index (SI) and Brightness 
Index (BI) calculated from whole sky imageries. SI shows the extent of the blueness and grayscale and BI indicates the extent of the 
brightness. Sun, cloud and blue sky areas are divided by SI and BI threshold. As an extension of ground-based observation to 
satellite-based observation, clouds area discriminated by ground-based observation overlay to satellite images. Through this 
experiment, the utilities of ground-based cloud observation are discussed. 
The proposed ground-based cloud observation method and its satellite-based extension should be connected to satellite products with 
high quality by implementation of sky and clouds observation covering a wide area. 
1. INTRODUCTION 
Clouds control energy budget on both local and global scales. 
Generally, it is well known that lower clouds cool the surface 
and upper clouds have the effects to warm the surface (Clement 
et al, 2009). Cumulus clouds especially in atmospheric 
boundary layer play crucial role in modulating the exchange of 
radiation, heat and moisture (Freedman et al. 2001). The size 
and the lifespan of cumulus clouds are small and short, 
therefore it is difficult to observe and monitor them spatially 
and temporally. 
Satellite-based observation and its products related to clouds 
properties have been useful to estimate some physical values 
such incident radiation/ Photosynthetic Active Radiation (PAR) 
and Fraction of PAR etc., and to be advanced various high 
quality satellite products. However, there are still some 
uncertainness such as cloud motion, cloud coverage, cloud type 
and these effects by satellite-based observation. Therefore, the 
efficient ground-based cloud observation is necessary to 
validate satellite-based observation such existing Terra & Aqua/ 
Moderate Resolution Imaging Spectroradiometer (MODIS) and 
under planning Global Change Observation Mission - Climate 
(GCOM-C) / Second generation GLobal Imager (SGLI) etc. 
Recently, the ground-based cloud observation systems have 
been developed by using whole sky camera in world widely 
instead of the existing visual observation (Calbo and Sabburg, 
2008; Yamashita and Yoshimura, 2008; Heinle et al., 2010). 
The purpose of this study is to discriminate the cloud and 
overlay the cloud areas with satellite-based images by the 
efficient and simple ground-based cloud observation using 
commercial based digital camera and fish eye lens in order to 
validate the satellite-based observation. In the paper, we mainly 
describe how to discriminate the cloud area on whole sky 
Images, how to overlay the cloud areas to the satellite-based 
images and the test experiment. Through this experiment, the 
utilities of ground-based cloud observation are discussed. 
2. GROUND-BASED CLOUD OBSERVATION 
2.1 Camera system 
Automatic-capturing Digital Fisheye Camera (ADFC) is the 
instruments to take and accumulate the whole sky imageries. 
ADFC consists of digital camera (Nikon, Coolpix4500) with 
fisheye lens (Nikon, Fisheye Converter FC-E8), waterproof 
hard case and remote controlled cable connected to PC 
(Tsuchida et al, 2005). 
In order to decrease the influence for CCD saturation caused by 
the strong sun light, the neutral density filter with 10% 
transparency (FUJIFILM, ND1.0) puts between the digital 
camera and the fisheye lens. The camera is set up to take 
imageries at every two-minute interval by fixed exposure of the 
aperture as F2.6 and shutter speed as 1/500s. The image size has 
2204pixels by 1704lines with RGB colors and JPEG (1/4 
compressed) format instead of RAW or Tiff format to 
accumulate the large volume of image files. In this study, we 
already have confirmed that the almost no influences between 
JPEG (1/4 compressed) and RAW/Tiff formats after image 
processing. Also, digital number (DN) of RGB channels can be 
used instead of radiance by fixing aperture and exposure. 
The head of digital camera of ADFC is fixed to north direction 
and levelled to horizon. 
2.2 Discrimination of cloud, blue sky and sun 
The sky conditions consist of each state of sun, clouds and blue 
sky. In order to discriminate the sky conditions from whole sky 
imageries, we use two indices which show the levels of the 
blueness/greyscale and the brightness calculated from the 
imageries. Here, the method how to discriminate the sky 
condition is described. Figure 1 shows the flowchart to classify 
cloud and blue sky areas from the whole sky imagery taken at 
the time (7).